US3100967A - Steam power plant - Google Patents

Steam power plant Download PDF

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US3100967A
US3100967A US62035A US6203560A US3100967A US 3100967 A US3100967 A US 3100967A US 62035 A US62035 A US 62035A US 6203560 A US6203560 A US 6203560A US 3100967 A US3100967 A US 3100967A
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steam
superheater
valve
line
bypass line
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Brunner Alfred
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Sulzer AG
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Sulzer AG
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01KSTEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
    • F01K9/00Plants characterised by condensers arranged or modified to co-operate with the engines
    • F01K9/04Plants characterised by condensers arranged or modified to co-operate with the engines with dump valves to by-pass stages
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01KSTEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
    • F01K7/00Steam engine plants characterised by the use of specific types of engine; Plants or engines characterised by their use of special steam systems, cycles or processes; Control means specially adapted for such systems, cycles or processes; Use of withdrawn or exhaust steam for feed-water heating
    • F01K7/16Steam engine plants characterised by the use of specific types of engine; Plants or engines characterised by their use of special steam systems, cycles or processes; Control means specially adapted for such systems, cycles or processes; Use of withdrawn or exhaust steam for feed-water heating the engines being only of turbine type
    • F01K7/22Steam engine plants characterised by the use of specific types of engine; Plants or engines characterised by their use of special steam systems, cycles or processes; Control means specially adapted for such systems, cycles or processes; Use of withdrawn or exhaust steam for feed-water heating the engines being only of turbine type the turbines having inter-stage steam heating
    • F01K7/24Control or safety means specially adapted therefor
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F22STEAM GENERATION
    • F22GSUPERHEATING OF STEAM
    • F22G3/00Steam superheaters characterised by constructional features; Details or component parts thereof
    • F22G3/008Protection of superheater elements, e.g. cooling superheater tubes during starting-up periods, water tube screens

Definitions

  • This invention relates to steam power plants including a steam-operated prime mover or steam-consuming machine and a steam generator comprising an evaporator and superheater, the plant further including a bypass line which branches oil between the superheater and prime mover and which contains a valve operable in dependence on an operating condition of the working substance.
  • the invention will hereinafter be described with reference to steam as the working substance, although it is not restricted thereto, and the word team as hereinafter used is intended to refer to vaporizable working substances generally.
  • the valve is operated in dependence on the steam pressure. If, for example, the valve in the line which admits steam to the prime mover is closed, the pressure in the live steam line rises. This pressure nise is utilized to open the valve in the bypass line.
  • the valve controlling admission of steam to the prime mover is closed in the case of less than fullload operation, then the time required until the pressure in the steam feed line to the prime mover has risen to an amount such that the valve in the bypass line responds may be so long that the superheater is in danger of burning out owing to the amount of steam stagnating therein.
  • the steam power plant according to the invention is characterized in that the valve in the bypass is controlled by a signal representative of steam rate of flow, which is developed or taken ofi in the region between the evaporator and the branching-off point of the bypass line'.
  • the bypass valve is so controlled that the amount of steam flowing through the superheater does not fall below a predetermined value, which is advantageously made variable in dependence on the load on the steam generator.
  • the invention ensures that the superheater cannot in any case burn out, since the bypass valve opens under control of the rate of steam flow signal as soon as the steam flow drops below a minimum value.
  • the invention also makes it possible to avoid opening of the safety valve. It is undesirable for the safety valve to open because after use it usually no longer closes so as to be steam-tight and then has to be overhauled or even replaced. In addition, steam is lost when the safety'valve opens.
  • the invention may also be embodied in steam power plants having single or repeated re-superheating, the output of each reheater being connected to a bypass line including a valve which is also controlled by the rate of I steam fiow signal which is developed between the evaporator and the branching-01f point of the bypass line downstream of the superheater.
  • the signal for control of the valve is formed by the pressure drop in at least one part of the superheater.
  • FIGURE of drawings is a diagram of a steam power plant according to the invention with single-pass re-superheating.
  • Reference character 1 denotes an evaporator and reference character 2 denotes the associated superheater.
  • a live steam line 40 leads to the high pressure part 3 of a steam turbine which drives an electrical generator 41.
  • the line 40 contains a valve 12 upstream of the inlet to the highpressure turbine 3.
  • a line 42 leads to a reheater 4 and from the latter a line 43 containing a valve 13 leads to the low-pressure turbine 5, also coupled to generator 41.
  • the steam outlet of the low-pressure turbine 5 is connected by a line 44 to a condenser 6, which is in turn connected by a line 45 to a feed tank 9.
  • the line 45 contains a condensate pump 7 and a preheater 8.
  • the feed tank 9 is connected by a line 46 to the evaporator 1 and the line 46 contains a feed pump 16 and a preheater 11.
  • a bypass line 47 branches .ofi? between superheater 2 and valve 12 and leads to the reheater 4. From the outlet of the reheater 4 a bypass line 47 branches off and leads into the line 44 connecting the outlet of low-pressure turbine 5 to the condenser 6.
  • the bypass line 47 contains a valve 24, a perforated diaphragm 25 for measurement of flow rate, a dynamic pressure measuring tube 48 and a Venturi tube 33.
  • the bypass line 47' contains a valve 30, a perforated diaphragm 29 for flow rate measurement, and a Venturi tube 49.
  • the pressure tube 48 is connected by a line 50 to a tank 34 containing feed water for cooling purposes.
  • the Venturi tube 33 is connected by a line 51 to the tank 34.
  • Line 51 however opens below the level of the water in the tank.
  • the supply of feed water to the tank 34 is effected through a line 52, which is connected to the line 46 on the high pressure side of the feed pump 10.
  • the line 52 contains a valve 53, which is controlled by a regulating means 54 dependent on the water level in the tank 34.
  • the Venturi tube 49 is connected by a line 71 to the condensate collector tank 72 below the condenser 6.
  • the valve 24 in the bypass line 47 is controlled by a signal representative of rate of steam flow.
  • the pressure drop in the superheater 2 is used for this purpose, lines .55 and 56 respectively being connected upstream and downstream of the superheater 2. These lines lead to a cylinder containing a piston.
  • 20 Connected. to the piston rod of the piston 20 is a lever 57 supported at a fixed pivot point 58. The upper end of the lever 57 in the drawing is connected by a piston rod 59 to a piston 22, into the cylinder of which there opens a hydraulic signal line 21.
  • Line 21 is connected, for example, to a loadresponsive signal generator (not shown) and thus supplies to the piston 22 a load-dependent signal. This signal serves as a reference with respect to which the rate of flow signal obtained from.
  • the piston rod of the piston 20 extends beyond its coupling to the lever 57 into the range of motion of one end of a lever 23.
  • Lever 23 is pivotally supported at a point 60 and the end thereof opposite the end engageable by the rod of piston '20 is connected to the spindle or actuating member 61 of the valve 24.
  • the spindle 6-1 is supported for linear motion in guides 61' between two springs 62 and 63.
  • Two lines 64 and 65 lead oif from opposite sides of the diaphragm 2 5 in the bypass line 47.
  • the line 65 is directly connected to one end of the cylinder of a piston 66.
  • Piston 66 is connected to the actuating member 67 of the valve 30 in bypass line 4-7.
  • the line 64 is indirectly connected to the cylinder of the piston 66 by way of a control slide 26, which can interrupt thetransmission of the pressure in the line 64 in the manner to be described hereinafter.
  • the control slide 26 is positioned to be engaged by one end of lever 57, beyond the coupling therewith of the piston 20. Slide 26 also bears against a spring 75.
  • a piston 68 is also connected to the actuating member 67 of the valve 30 and has a somewhat larger cross-section than the piston 66.
  • To the cylinder of pistons 68 are connected two lines 69 and 70- which lead to opposite sides of the diaphragm 29 in line 47.
  • the pistons heater 4. Here the steam is again superheated and is then taken through the line 43 to the low-pressure turbine 5, where it is. further expanded.
  • the expanded steam is finally condensed in the condenser 6, and the condensae is taken through the preheater 8, the feed tank 9 and preheater 11 to the evaporator 1 by means of the pumps 7 and .10.
  • a steam power plant comprising evaporator, a
  • a steam consuming machine conduit means to conduct steam from'the evaporator through the superheater to said machine, a bypass line connected into said conduit means between the superheater and machine, a valve in said bypass line, means to develop a signal representative of the rate of steam flow at a location in said conduit means between the evaporator and the connection of the bypass line into said conduit means, and means responsive to said signal to open said valve upon decline in said rate of steam flow below a specified level.
  • a steam power plant comprising an evaporator, a
  • a steam power plant comprising an evaporator, a superhcater, a steam consuming machine, conduit means to conduct steam from the evaporator through the; superheater to said machine, a bypass line connected into said conduit means between the superheater and machine, a valve in said bypass line, and means to open said valve in response to decline below a specified level in the steam pressure difference between two points in the superheater located upstream anddownstream with respect to each otherin the sense of steam flow through the superheater. 4.
  • a steam power plant comprising an evaporator, a superheater, a steam consuming machine having'fi-rst and second stages, a reheater, conduit means to conneotthe evaporator, superheater, first stage, rchea-ter and second stage in series for steam flow therethrough, 'a first bypass line connected into said conduit means between the superheater and first stage, a second bypass line connected into said conduit means between the reheater and second stage, a separate valve in each of said bypass lines, means to generate a signal representative of the rate of steam flow through said superheater, and means responsive to said signal to control the opening of said valves.
  • a steam power plant comprising an evaporator, a superheater, a steam consuming machine having first and second stages, a reheater, conduit means to connect the evaporator, superheater, first stage, reheater and second stage in series for steam flow therethrough, a first bypass line connected into said conduit means between the superheater and first stage, a second bypass line connected into said conduit means between the reheater and second stage, a separate valve in each of said bypass lines, and
  • a steam power plant comprising an evaporator, a superheater, a steam consuming machine having first and second stages, a reheater, conduit means to connect the evaporator, superheater, first stage, rcheater and second stage in series for steam flow therethrough, a first bypass line connected into said conduit means between the superheater and first stage, a second bypass line con nected into said conduit means between the reheater and second stage, a separate valve in each of said bypass lines, means responsive to variations in the pressure difter'ence between two points in said superheater upstream and downstream of each other in the sense of steam flow through said superheater to control the valve in said first bypass line, and means responsive to the rate of flow of steam through said first bypass line to control the valve in said second bypass line.
  • a steam power plant comprising an evaporator, a superheater, a steam consuming machine having first and second stages, a reheater, conduit means to connect the evaporator, superheater, first stage, reheater and second stage in series for steam flow therethrough, a first bypass line connected into said conduit means between the superheater and first stage, a second bypass line connected into said conduit means between the reheater and second stage, a separate valve in each of said bypass lines, means responsive to variations in the pressure difierence between two points in said superheater upstream and downstream of each other in the sense of steam flow through said superhea-ter to control the valve in said first bypass line 5 and means responsive to said pressure-(inference and to the rate of flow of steam through said first bypass line to control the valve in said second bypass line.
  • a steam power plant comprising an evaporator, a

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Control Of Steam Boilers And Waste-Gas Boilers (AREA)

Description

v Jnvenfor I 44/260 Fem/wee 4f7'0FA/6Y5' United States Patent ()fiice 3,100,967 Patented Aug. 20, 1963 3,100,967 STEAM POWER PLANT Alfred Brnnner, Winterthnr, Switzerland, assignor to Sulzer Freres, Societe Anonyme, Winterthur, Switzerland, a Swiss company Filed Oct. 11, 1960, Ser. No. 62,035 Claims priority, application Switzerland Oct. 15, 1359 8 Claims. (Cl; 60-73) This invention relates to steam power plants including a steam-operated prime mover or steam-consuming machine and a steam generator comprising an evaporator and superheater, the plant further including a bypass line which branches oil between the superheater and prime mover and which contains a valve operable in dependence on an operating condition of the working substance. The invention will hereinafter be described with reference to steam as the working substance, although it is not restricted thereto, and the word team as hereinafter used is intended to refer to vaporizable working substances generally.
In known plants of this kind, the valve is operated in dependence on the steam pressure. If, for example, the valve in the line which admits steam to the prime mover is closed, the pressure in the live steam line rises. This pressure nise is utilized to open the valve in the bypass line. When the valve controlling admission of steam to the prime mover is closed in the case of less than fullload operation, then the time required until the pressure in the steam feed line to the prime mover has risen to an amount such that the valve in the bypass line responds may be so long that the superheater is in danger of burning out owing to the amount of steam stagnating therein. To obviate this danger, the steam power plant according to the invention is characterized in that the valve in the bypass is controlled by a signal representative of steam rate of flow, which is developed or taken ofi in the region between the evaporator and the branching-off point of the bypass line'.
.In the case of interest for the invention, the bypass valve is so controlled that the amount of steam flowing through the superheater does not fall below a predetermined value, which is advantageously made variable in dependence on the load on the steam generator. The invention ensures that the superheater cannot in any case burn out, since the bypass valve opens under control of the rate of steam flow signal as soon as the steam flow drops below a minimum value. The invention also makes it possible to avoid opening of the safety valve. It is undesirable for the safety valve to open because after use it usually no longer closes so as to be steam-tight and then has to be overhauled or even replaced. In addition, steam is lost when the safety'valve opens.
The invention may also be embodied in steam power plants having single or repeated re-superheating, the output of each reheater being connected to a bypass line including a valve which is also controlled by the rate of I steam fiow signal which is developed between the evaporator and the branching-01f point of the bypass line downstream of the superheater.
According to one embodiment of the invention, the signal for control of the valve is formed by the pressure drop in at least one part of the superheater.
Further features of the invention will be apparent from the following description of one exemplified embodiment in conjunction with the accompanying drawings.
In these drawings the single FIGURE of drawings is a diagram of a steam power plant according to the invention with single-pass re-superheating. Reference character 1 denotes an evaporator and reference character 2 denotes the associated superheater. From the superheater 2 a live steam line 40 leads to the high pressure part 3 of a steam turbine which drives an electrical generator 41. The line 40 contains a valve 12 upstream of the inlet to the highpressure turbine 3. From the highpressure turbine3 a line 42 leads to a reheater 4 and from the latter a line 43 containing a valve 13 leads to the low-pressure turbine 5, also coupled to generator 41. 'The steam outlet of the low-pressure turbine 5 is connected by a line 44 to a condenser 6, which is in turn connected by a line 45 to a feed tank 9. The line 45 contains a condensate pump 7 and a preheater 8. The feed tank 9 is connected by a line 46 to the evaporator 1 and the line 46 contains a feed pump 16 and a preheater 11. i
From the live steam line 40, a bypass line 47 branches .ofi? between superheater 2 and valve 12 and leads to the reheater 4. From the outlet of the reheater 4 a bypass line 47 branches off and leads into the line 44 connecting the outlet of low-pressure turbine 5 to the condenser 6. The bypass line 47 contains a valve 24, a perforated diaphragm 25 for measurement of flow rate, a dynamic pressure measuring tube 48 and a Venturi tube 33. The bypass line 47' contains a valve 30, a perforated diaphragm 29 for flow rate measurement, and a Venturi tube 49. The pressure tube 48 is connected by a line 50 to a tank 34 containing feed water for cooling purposes. The Venturi tube 33 is connected by a line 51 to the tank 34. Line 51 however opens below the level of the water in the tank. The supply of feed water to the tank 34 is effected through a line 52, which is connected to the line 46 on the high pressure side of the feed pump 10. The line 52 contains a valve 53, which is controlled by a regulating means 54 dependent on the water level in the tank 34. The Venturi tube 49 is connected by a line 71 to the condensate collector tank 72 below the condenser 6.
The valve 24 in the bypass line 47 is controlled by a signal representative of rate of steam flow. The pressure drop in the superheater 2 is used for this purpose, lines .55 and 56 respectively being connected upstream and downstream of the superheater 2. These lines lead to a cylinder containing a piston. 20 Connected. to the piston rod of the piston 20 is a lever 57 supported at a fixed pivot point 58. The upper end of the lever 57 in the drawing is connected by a piston rod 59 to a piston 22, into the cylinder of which there opens a hydraulic signal line 21. Line 21 is connected, for example, to a loadresponsive signal generator (not shown) and thus supplies to the piston 22 a load-dependent signal. This signal serves as a reference with respect to which the rate of flow signal obtained from. the pressure drop in the superheater 2 is compared. The piston rod of the piston 20 extends beyond its coupling to the lever 57 into the range of motion of one end of a lever 23. Lever 23 is pivotally supported at a point 60 and the end thereof opposite the end engageable by the rod of piston '20 is connected to the spindle or actuating member 61 of the valve 24. The spindle 6-1 is supported for linear motion in guides 61' between two springs 62 and 63.
Two lines 64 and 65 lead oif from opposite sides of the diaphragm 2 5 in the bypass line 47. Of these the line 65 is directly connected to one end of the cylinder of a piston 66. Piston 66 is connected to the actuating member 67 of the valve 30 in bypass line 4-7. The line 64 is indirectly connected to the cylinder of the piston 66 by way of a control slide 26, which can interrupt thetransmission of the pressure in the line 64 in the manner to be described hereinafter. The control slide 26 is positioned to be engaged by one end of lever 57, beyond the coupling therewith of the piston 20. Slide 26 also bears against a spring 75. A piston 68 is also connected to the actuating member 67 of the valve 30 and has a somewhat larger cross-section than the piston 66. To the cylinder of pistons 68 are connected two lines 69 and 70- which lead to opposite sides of the diaphragm 29 in line 47. The pistons heater 4. Here the steam is again superheated and is then taken through the line 43 to the low-pressure turbine 5, where it is. further expanded. The expanded steam is finally condensed in the condenser 6, and the condensae is taken through the preheater 8, the feed tank 9 and preheater 11 to the evaporator 1 by means of the pumps 7 and .10. During normal operation, the pressure drop in the snperheater 2 is such that the piston 26 is forced by that pressuredrop-to the left in the drawing, taking its piston rod' clear of lever 23, and the valve 24 is closed under the action-of the spring 62 which shifts the spindle '61 to theright. The valve 30* is also closed, because there is no, pressure drop at the diaphragms 2.5 and 29, spindle 67 being also moved to the right. a
It .for some reason the flow in the superheater is re duced, vfor example because the valves 12 and 13 are closed, then the piston 29 moves to the right in the drawing as a result of the lowerpressure drop in the superheater Zand the extended end of its piston rod strikes against thetwo-ar-med lever 23, so that the spindle 61 is shifted to the left andv'alve 2A is opened, steam then flowing out of the live steam line 4t) through the bypass line 47 to the reheater 4. This fiow of steam produces a pressure drop at the diaphragm 2'5, and this pressure drop takes efiect on the piston 66. Spindle 67 moves to the left and opens the valve 30, so that the steam passes from the intermediate superheater 4' through the bypass.
line 47 to the condenser 6. 'The pressure drop at the diaphragm 25 can take efiecton the piston 66 because, on the movement of the piston 20 to the right, the extended end of the lever 57 also moves the control slide 26th the right, establishing communication'between line 64 and its extension 64' via the cylinder 26' in which slide 26 moves. In this way, a steam flow is thus maintained in thesuperheater 2 and in the reheater 4 so that these elements can:
7 27 are normally so proportioned with respect to one an otherthat substantially the same amount of steam is taken ofi through the bypass line 47' downstream of the reheater 4 as is supplied through the bypass line 47 upstream of the reheater 4. In special cases, the quantities can valso be made different from one another. 7
While the invention has been described herein in terms of a number of preferred embodiments, the invention is not limited to the details of construction thus illustrated and described, but is rather set forth in the appended claims. 1
I claim:
1'. A steam power plantcomprising evaporator, a
'superhcater, a steam consuming machine, conduit means to conduct steam from'the evaporator through the superheater to said machine, a bypass line connected into said conduit means between the superheater and machine, a valve in said bypass line, means to develop a signal representative of the rate of steam flow at a location in said conduit means between the evaporator and the connection of the bypass line into said conduit means, and means responsive to said signal to open said valve upon decline in said rate of steam flow below a specified level.
2. A steam power plant comprising an evaporator, a
to conduct, steam from the evaporator through the. superheater to said machine, a bypass line connected into said conduit means between the superheater and machine, a valve in said bypass line, and means to open said valve in response to decline below a specified level in the steam pressure difference between two points located upstream and downstream of each other in the sense of steam flow between the evaporator and the connection of the bypass line into said conduit means.
'3. A steam power plant comprising an evaporator, a superhcater, a steam consuming machine, conduit means to conduct steam from the evaporator through the; superheater to said machine, a bypass line connected into said conduit means between the superheater and machine, a valve in said bypass line, and means to open said valve in response to decline below a specified level in the steam pressure difference between two points in the superheater located upstream anddownstream with respect to each otherin the sense of steam flow through the superheater. 4. A steam power plant comprising an evaporator, a superheater, a steam consuming machine having'fi-rst and second stages, a reheater, conduit means to conneotthe evaporator, superheater, first stage, rchea-ter and second stage in series for steam flow therethrough, 'a first bypass line connected into said conduit means between the superheater and first stage, a second bypass line connected into said conduit means between the reheater and second stage, a separate valve in each of said bypass lines, means to generate a signal representative of the rate of steam flow through said superheater, and means responsive to said signal to control the opening of said valves.
5. A steam power plant comprising an evaporator, a superheater, a steam consuming machine having first and second stages, a reheater, conduit means to connect the evaporator, superheater, first stage, reheater and second stage in series for steam flow therethrough, a first bypass line connected into said conduit means between the superheater and first stage, a second bypass line connected into said conduit means between the reheater and second stage, a separate valve in each of said bypass lines, and
' means responsive to variations in the steam pressure difference between two points in said superheater upstream and downstream of each other in the sense of steam flow through said superheater to control the opening or" said valves. i
6. A steam power plant comprising an evaporator, a superheater, a steam consuming machine having first and second stages, a reheater, conduit means to connect the evaporator, superheater, first stage, rcheater and second stage in series for steam flow therethrough, a first bypass line connected into said conduit means between the superheater and first stage, a second bypass line con nected into said conduit means between the reheater and second stage, a separate valve in each of said bypass lines, means responsive to variations in the pressure difter'ence between two points in said superheater upstream and downstream of each other in the sense of steam flow through said superheater to control the valve in said first bypass line, and means responsive to the rate of flow of steam through said first bypass line to control the valve in said second bypass line.
7. A steam power plant comprising an evaporator, a superheater, a steam consuming machine having first and second stages, a reheater, conduit means to connect the evaporator, superheater, first stage, reheater and second stage in series for steam flow therethrough, a first bypass line connected into said conduit means between the superheater and first stage, a second bypass line connected into said conduit means between the reheater and second stage, a separate valve in each of said bypass lines, means responsive to variations in the pressure difierence between two points in said superheater upstream and downstream of each other in the sense of steam flow through said superhea-ter to control the valve in said first bypass line 5 and means responsive to said pressure-(inference and to the rate of flow of steam through said first bypass line to control the valve in said second bypass line.
8. A steam power plant comprising an evaporator, a
downstream. of each other in the sense of steam flow through said superheater to control said first valve, and means responsive to steam fiow through said first bypass line and to said pressure difference to control said second valve.
References Cited in the file of this patent UNITED STATES PATENTS 1,964,773 SIImOt July 3, 1934 2,098,803 Harris Nov. 9, 1937 FOREIGN PATENTS Great Britain Q Sept. 30, '1926

Claims (1)

1. A STEAM POWER PLANT COMPRISING AN EVAPORATOR, A SUPERHEAT, A STEAM CONSUMING MACHINE, CONDUIT MEANS TO CONDUCT STEAM FROM THE EVAPORATOR THROUGH THE SUPERHEATER TO SAID MACHINE, A BYPASS LINE CONNECTED INTO SAID CONDUIT MEANS BETWEEN THE SUPERHEATER AND MACHINE, A VALVE IN SAID BYPASS LINE, MEANS TO DEVELOP A SIGNAL REPRESENTATIVE OF THE RATE OF STEAM FLOW AT A LOCATION IN SAID CONDUIT MEANS BETWEEN THE EVAPORATOR AND THE CONNECTION OF THE BYPASS LINE INTO SAID CONDUIT MEANS, AND MEANS RESPONSIVE TO SAID SIGNAL TO OPEN SAID VALVE UPON DECLINE IN SAID RATE OF STEAM FLOW BELOW A SPECIFIED LEVEL.
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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3575002A (en) * 1965-06-15 1971-04-13 Combustion Eigineering Inc Combination fossil fuel and superheated steam nuclear power plant
US3667230A (en) * 1971-01-26 1972-06-06 Cem Comp Electro Mec Process for the rational exchange of heat in counter-current heat exchanges where the exchanges are unbalanced
US3882680A (en) * 1972-04-18 1975-05-13 Babcock & Wilcox Co By-pass system
US20120073289A1 (en) * 2010-09-29 2012-03-29 General Electric Company System and method for cooling an expander
US11066961B2 (en) * 2016-05-10 2021-07-20 Kobe Steel, Ltd. Exhaust heat recovery system

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB244773A (en) * 1924-12-18 1926-09-30 Siemens Schuckertwerke Gmbh Improvements in or relating to safety devices for water tube boilers
US1964773A (en) * 1930-05-21 1934-07-03 Katherine Smoot Feed water control system
US2098803A (en) * 1936-01-15 1937-11-09 Gen Electric Elastic fluid turbine arrangement

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB244773A (en) * 1924-12-18 1926-09-30 Siemens Schuckertwerke Gmbh Improvements in or relating to safety devices for water tube boilers
US1964773A (en) * 1930-05-21 1934-07-03 Katherine Smoot Feed water control system
US2098803A (en) * 1936-01-15 1937-11-09 Gen Electric Elastic fluid turbine arrangement

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3575002A (en) * 1965-06-15 1971-04-13 Combustion Eigineering Inc Combination fossil fuel and superheated steam nuclear power plant
US3667230A (en) * 1971-01-26 1972-06-06 Cem Comp Electro Mec Process for the rational exchange of heat in counter-current heat exchanges where the exchanges are unbalanced
US3882680A (en) * 1972-04-18 1975-05-13 Babcock & Wilcox Co By-pass system
US20120073289A1 (en) * 2010-09-29 2012-03-29 General Electric Company System and method for cooling an expander
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